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To those of you who dream of going to space: Sorry, but that may never happen. However, NASA is once again counting on the public for help understanding what's beyond our world. All we have to do is look at some photos online.

Today marks the launch of Backyard Worlds: Planet 9, a project that relies on everyday people to help scientists identify objects near our solar system. These celestial bodies appear to move across the sky, but computers have a hard time finding things like brown dwarfs and planets in the noisy images. This means manually searching the photos is the most effective method to get the job done.

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americanmuseumofnaturalhistoryarizonastateuniversityastronomyastrophysicsbackyardworldsplanet9browndwarfclydetombaughdradamcschneiderinternetjackiefahertynasaouterspaceplanetplanetsplutosciencespacespacetelescopescienceinstitutesuntwitteruniversityofcaliforniaberkeleyzooniverseWed, 15 Feb 2017 19:57:00 -050021|21714869https://www.engadget.com/2016/10/07/researchers-push-moores-law-with-a-1-nanometer-transistor-gate/https://www.engadget.com/2016/10/07/researchers-push-moores-law-with-a-1-nanometer-transistor-gate/https://www.engadget.com/2016/10/07/researchers-push-moores-law-with-a-1-nanometer-transistor-gate/#comments
Ready for some hardcore science about transistor elements that are a fraction of the width of a human hair? Good, because that's what this post is all about. "The semiconductor industry has long assumed that any gate below 5 nanometers wouldn't work, so anything below that was not even considered," University of California at Berkeley researcher Sujai Desay says. In recent years, though, that assertion has looked shaky, and now it's been thoroughly disproved thanks to the discoveries made by scientists at UC Berkeley and the magic of carbon nanotubes. Or, as they're more commonly known, graphene.

See that minuscule component in the image above? That's a wireless sensor, and someday, doctors could slip it into our bodies to monitor our organs like a microscopic Fitbit or even to give quadri- and paraplegics the power to control robotic arms or legs. A team of scientists from the University of California, Berkeley have developed an early iteration of the sensor that's about the size of a grain of rice. Each sensor has a piezoelectric crystal that can convert ultrasound vibrations into energy. It also allows the teensy device to beam back data collected from nerve cells in the brain if it's used to control bionic limbs.

We've been inching closer to real-life invisibility cloaks for a bit now, but going full on Harry Potter in the Hogwarts library is probably still a ways off. The latest advancement in metamaterial-based vanishing tech from Iowa State University guards whatever it's placed on from cameras, according to a paper published in Nature. The naked eye? Not so much. And even those cameras can't hide it from a human viewing a video feed, only other machines or perhaps radar.

The researchers achieved this by embedding split ring resonators filled with galinstan into silicone sheets. Stretching those sheets is a form of tuning of sorts, and allowed the scientists to suppress certain radar waves up to about 75 percent. This type of tech could be used in a stealth fighter jet for example, as everything RF notes.

As much as I love watching movies, I'm not doing it for work and don't really need to worry about finding a specific scene or line of dialogue as fast as possible. But I'm not a film scholar or student, so those folks have it a little tougher when it comes to such matters. To that end, researchers have at the University of California Berkeley have developed SceneSkim. It's a bit of tech that leverages captions, scripts and plot summaries to speed up searching for scenes in flicks rather than manually fast forwarding or rewinding. There's a video of it in action below and it looks pretty slick, actually and should be a boon for the people who need quick access to specific movie scenes.

Sugar is basically ubiquitous and it looks like it could be used to make morphine, which is a refined form of heroin. Recent research shows that a genetically modified strain of yeast, when exposed to sugar, could be used to ferment the opioid. Yes, essentially, you could homebrew your own scag. I know what you're thinking: "This sounds like madness." But there's some proof behind it. Researchers from the University of California Berkeley and Concordia University in Canada presented an almost complete means to turn glucose to morphine, while scientists from the University of Calgary supplied the missing piece that completes the process. The idea wasn't to flood the streets with home-made heroin. No, the plan is much more noble than that: to produce "cheaper, less addictive, safer and more-effective" painkillers, according to Nature.

Computers are normally limited by the fixed nature of their chipsets: once the silicon is out of the factory, its capabilities are forever locked in. The City College of New York and University of California Berkeley have jointly developed a technique that could break chips free of these prisons and speed along quantum computing. They found that hitting gallium arsenide with a laser light pattern aligns the spins of the atoms under the rays, creating a spintronic circuit that can re-map at a moment's notice. The laser could be vital to quantum computers, which can depend heavily or exclusively on spintronics to work: a simple shine could get electrons storing a much wider range of numbers and consequently handling many more calculations at once. Research is only just now becoming public, however; even though gallium arsenide is common in modern technology, we'll need to be patient before we find quantum PCs at the local big-box retail chain. Despite this, we could still be looking at an early step in a shift from computers with many single-purpose components to the abstracted, all-powerful quantum machines we've held in our science fiction dreams.

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city college new yorkcity college of new yorkcitycollegenewyorkcitycollegeofnewyorkelectron spinelectronspingallium arsenidegalliumarsenidelaserlasersquantumquantum computerquantum computingquantumcomputerquantumcomputingresearchsciencespintronicspintronicsuc berkeleyucberkeleyuniversity of california berkeleyuniversityofcaliforniaberkeleyWed, 27 Jun 2012 04:26:00 -040021|20266678https://www.engadget.com/2011/10/08/clash-is-an-adorable-cloth-climbing-roach-bot-video/https://www.engadget.com/2011/10/08/clash-is-an-adorable-cloth-climbing-roach-bot-video/https://www.engadget.com/2011/10/08/clash-is-an-adorable-cloth-climbing-roach-bot-video/#comments

Generally the words "roach" and "adorable" don't get thrown together. But, one look at the video after the break and you'll understand. This six-legged successor to UC Berkeley's DASH scampers not just horizontally, but vertically -- so long as the material it's climbing is cloth. All motion is handled by the bot's front four legs, while the rear two provide stabilization. The CLASH is able to adhere to cloth because its feet have small claws that allow it to grip the fabric, while its appendages scurry about at up to 34 strides per second. Its top speed of 24 centimeters a second may not sound like much, but considering the pest-inspired design is only 10 centimeters long, it's actually quite a brisk pace. Trust us, you don't want to miss watching it in action after the break.
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clashclimbing botclimbingbotcockroachdashroachroach botroachbotrobotrobotsuc berkeleyucberkeleyuniversity of california berkeleyuniversityofcaliforniaberkeleyvideoSat, 08 Oct 2011 00:22:00 -040021|20076478https://www.engadget.com/2011/07/22/samsung-studies-3d-viewing-discomfort-finds-out-bloggers-dont/https://www.engadget.com/2011/07/22/samsung-studies-3d-viewing-discomfort-finds-out-bloggers-dont/https://www.engadget.com/2011/07/22/samsung-studies-3d-viewing-discomfort-finds-out-bloggers-dont/#comments

Judging by the headlines today, Samsung's 3D R&D department made a huge mistake, just check them out: "Who Could Have Guessed: 3D Hurts Your Eyes", "Samsung-funded study finds 3D video causes extra eye strain, fatigue", "Samsung study finds that 3D video causes eye strain, fatigue". It seems obvious that Samsung's research grant financing a UC Berkeley study published in the Journal of Vision was wasted, except for one minor issue -- all of those headlines are wrong. "The zone of comfort: Predicting visual discomfort with stereo displays" is actually trying to find out why 3D-related eyestrain happens. That it can and does happen with poorly formatted video, whether 2D, 3D or otherwise, is already known.

Scrolling down beyond the abstract reveals the prof's data actually indicated a wider comfort zone than 3D video producers commonly assumed with their percentage rule of thumb. It's a Friday night and you don't have to pick thumbing through dry descriptions of experiments over whatever your plans are, but that's why you have us. Shockingly, companies desperately hawking 3D tech are busy making it better instead of undermining their own products, but you'd have to actually read the study to find out for sure.
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3d3d tv3dtveyestrainjournal of visionjournalofvisionsamsungstudyuc berkeleyucberkeleyuniversity of california berkeleyuniversityofcaliforniaberkeleyFri, 22 Jul 2011 21:03:00 -040021|19998583https://www.engadget.com/2011/05/16/paralyzed-student-uses-robotic-exoskeleton-to-walk-at-college-gr/https://www.engadget.com/2011/05/16/paralyzed-student-uses-robotic-exoskeleton-to-walk-at-college-gr/https://www.engadget.com/2011/05/16/paralyzed-student-uses-robotic-exoskeleton-to-walk-at-college-gr/#comments

Austin Whitney hasn't been able to walk since a 2007 car crash left him paralyzed, but on Saturday the 22-year-old triumphantly strode across the stage to accept his degree from UC Berkeley. He had a little help, in the form of a specially crafted robotic exoskeleton developed by Berkeley engineering professor Homayoon Kazerooni. Kazerooni and his team designed the exoskeleton with lightness and affordability in mind, resisting the urge to load it up with expensive hardware and tethering the mechanized walker to a backpack that houses a computer and a rechargeable, eight-hour battery. As a result, the Austin walker won't enable the kind of acrobatic leaps that would make Lt. Rasczak proud, but its reduced mobility comes at a reduced cost of just $15,000. That's certainly not an impulse buy, though it's a welcomed alternative to otherexoskeletons that retail for $100,000 or more. Walk past the break for a video of Whitney's momentous steps, along with a clip of Kazerooni describing his creation.
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austin whitneyaustinwhitneyberkeleycollegecollege graduationcollegegraduationcommencementcostdesignexoskeletongraduationhealthmoneyparalyzedparaplegicrechargeablerechargeable batteryrechargeablebatteryrobotic exoskeletonroboticexoskeletonroboticsstudentsuc berkeleyucberkeleyuniversity of california berkeleyuniversityofcaliforniaberkeleyvideowalkerwalkingMon, 16 May 2011 08:45:00 -040021|19941175https://www.engadget.com/2009/09/01/uc-berkeley-researchers-tout-worlds-smallest-semiconductor-lase/https://www.engadget.com/2009/09/01/uc-berkeley-researchers-tout-worlds-smallest-semiconductor-lase/https://www.engadget.com/2009/09/01/uc-berkeley-researchers-tout-worlds-smallest-semiconductor-lase/#comments

Scientists at the Norfolk State University may laid claim to a "world's smallest laser" title just a few short weeks ago with the aid of some newfangled "spasers," but it looks like the folks at UC Berkeley at hot on their heels with some tiny lasers of their own, and they've now announced what they claim to be the worlds smallest semiconductor laser. Unlike Norfolk State's solution, the Berkeley researchers apparently relied primarily on standard semiconductor materials and fabrication technologies commonly used today, but devised a new means to squeeze the visible light into a 5 nanometer gap (about the size of a single protein molecule), while also using some newly-engineered "hybrid surface plasmons" to keep the light from dissipating as it moves along. That, the researchers say, represents nothing short of a "new milestone in laser physics," and could pave the way for everything from new nanolasers that can probe, manipulate and characterize DNA molecules to new breakthroughs in computing that could see light replacing electronic circuitry "with a corresponding leap in speed and processing power."

Researchers at the University of California, Berkeley, the University of Michigan and MIT have created glass "leaves" with networks of veiny channels filled with water. The smallest channels extend all the way to the edges of the leaf, where open ends allow water to evaporate, which draws water along the central stem of the leaf -- at a rate of about 1.5 centimeters per second. The glass leaves have been wired for electricity by adding metal plates to the walls of the central stems and connecting them to a circuit. Researchers then charge the plates and the water inside the stems creates two conducting layers separated by an insulating layer, which acts as a capacitor. The waterflow is then periodically interrupted with air bubbles, and every time a bubble passes through the plates a small electrical current is generated -- about 2 - 5 microvolts per bubble. The team thinks that on a large scale, artificial trees could be use to generate large amounts of energy entirely through evaporation.
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artificial treeartificial treesartificialtreeartificialtreeselectricityglass leafglass leavesglassleafglassleavesleavesleavfmiscmitplantplantspowerpower generationpowergenerationuniversity of california at berkeleyuniversity of california berkeleyuniversity of michiganuniversityofcaliforniaatberkeleyuniversityofcaliforniaberkeleyuniversityofmichiganMon, 03 Aug 2009 04:13:00 -040021|19116689https://www.engadget.com/2009/07/25/monkeys-and-scientists-develop-persistent-plug-and-play-contro/https://www.engadget.com/2009/07/25/monkeys-and-scientists-develop-persistent-plug-and-play-contro/https://www.engadget.com/2009/07/25/monkeys-and-scientists-develop-persistent-plug-and-play-contro/#comments

While we've seen some pretty amazing things so far with computers jacked into human and monkey brains, systems so far have had to be re-learned each session by their subjects. In a new development, researchers at Berkeley have managed to get their monkeys to develop a "memory" for the controls, and recall them instantly each day. To do this, the scientists kept track of specific neurons from day to day -- a little tough to do, but obviously worth the hassle. It's good news for future brain-to-computer interfaces that will enable the disabled and the truly lazy to perform tasks and kick ass through the mere power of thought, but we're a little afraid of giving these monkeys too much in the way of internet access: the world doesn't need another 4chan.
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berkeleybrain interfacebrain scanbraininterfacebrainscancomputer brain interfacecomputer to brain interfacecomputerbraininterfacecomputertobraininterfacemonkeysrobotsuniversity of california berkeleyuniversityofcaliforniaberkeleywearablesSat, 25 Jul 2009 16:07:00 -040021|19109588https://www.engadget.com/2009/07/22/cellscope-the-cellphone-microscope-gets-uv-upgrade-to-spot-tin/https://www.engadget.com/2009/07/22/cellscope-the-cellphone-microscope-gets-uv-upgrade-to-spot-tin/https://www.engadget.com/2009/07/22/cellscope-the-cellphone-microscope-gets-uv-upgrade-to-spot-tin/#comments

It was over a year ago that UC Berkeley introduced the world to CellScope, the 60x microscope for cellphones made from cheap, off the shelf components (like a re-purposed belt clip). Now, even though we're disappointingly still not seeing this thing in stores, there's an upgraded version able to take pictures of even smaller nasties. Using a filter the scope can now spot microscopic critters tagged with dye that glows under fluorescent light -- things like Mycobacterium tuberculosis (that's the cause of TB if you, like us, lack a med degree). A software app is able to then count the number of cells within a given sample and tell you whether to worry about that annoying cough. There's still no word on whether this product will ever actually start scoping out such things in the wild, but we certainly hope it will -- if only so that we can keep our vast collection of cellphone accessories complete. Video after the break.

It was over a year ago that UC Berkeley introduced the world to CellScope, the 60x microscope for cellphones made from cheap, off the shelf components (like a re-purposed belt clip). Now, even though we're disappointingly still not seeing this thing in stores, there's an upgraded version able to take pictures of even smaller nasties. Using a filter the scope can now spot microscopic critters tagged with dye that glows under fluorescent light -- things like Mycobacterium tuberculosis (that's the cause of TB if you, like us, lack a med degree). A software app is able to then count the number of cells within a given sample and tell you whether to worry about that annoying cough. There's still no word on whether this product will ever actually start scoping out such things in the wild, but we certainly hope it will -- if only so that we can keep our vast collection of cellphone accessories complete. Video after the break.